Our previous works on the feedback instability in the magnetosphere-ionosphere (M-I) coupling system under a local approximation have revealed that the Kelvin-Helmholtz (K-H) type instability driven by enhanced E×B flow shear deforms auroral arc-like structures and leads to vortex formation followed by turbulence transition. However, global properties of the auroral growth have not been understood well except for a few basic properties of auroral arc structure formation elongated in the longitudinal direction.
In this study, we have performed a nonlinear simulation of the feedback instability in a non-local M-I coupling with the dipole field configuration to investigate nonlinear evolution of auroral fine structures by means of a novel numerical simulation code for a set of the reduced magnetohydrodynamic equations with a non-uniform kinematic viscosity in the magnetosphere and the two-fluid equations in the ionosphere. The simulation results clearly demonstrate transition to a turbulent state after convective growth of auroral fine structures and the succeeding K-H type instability. In addition, we have observed expansion of auroral turbulent structures broadening into the latitudinal directions as well as in the wave number spectrum in the nonlinear stage.